WO2014048662A1 - Measuring device for process automation technology - Google Patents

Abstract

The invention relates to a measuring device (1) for process automation technology, for measuring at least one process variable of a medium, wherein a regulation/control unit (3) is provided which measures the process variable with at least one specifiable clock rate and provides a measured value, wherein an energy requirement of the measuring device (1) is connected to the clock rate. A display/operating unit (2) is provided, which displays the measured value and/or enables the measuring device (1) to be operated or parameters to be input thereon. The invention includes the fact that the display/operating unit (2) switches the regulation/control unit (3) of the measuring device (1) from a measuring mode into an operating mode. In the operating mode, the regulation/control unit (3) measures the process variable with a first clock rate, and in the measuring mode, the regulation/control unit (3) measures the process variable with a second clock rate. The first clock rate and the second clock rate are defined such that the second clock rate is greater than the first clock rate and the overall energy requirement of the measuring device (1) is identical in the operating mode and in the measuring mode.

Description

 Measuring device of process automation technology

The invention relates to a measuring device of the process automation technology for measuring at least one process variable of a medium, wherein a control / control unit is provided which measures the process variable to at least a predetermined clock rate and provides as a measured value, with the clock rate, an energy demand of the measuring device is connected, wherein a display / control unit is provided, which represents the measured value and / or allows an operation or parameter input to the meter.

The measuring devices, the measuring devices or the sensors of the

Process automation techniques monitor or measure process sizes of media that vary depending on the nature of the process - e.g. synthesizing a medium - subject to major changes in a relatively short time. Such dynamic processes thus require that the time intervals between the individual measured values should be as low as possible. It should therefore be measured as often as possible in order to obtain an appropriate temporal resolution. However, this is the problem of

Energy requirements for the measurements contrary, with a higher

Measurement accuracy is usually associated with increased energy requirements. For 4 ... 20 mA measuring instruments, the energy is limited in principle. Depending on the configuration, however, components - e.g. Power supplies - for higher

Services correspondingly expensive or expensive. Thus, it is quite cumbersome to increase the number of measurement data or measurement points. Another limitation is the physical measuring principle that is applied and thus also specifies a lower limit for the temporal resolution. It may also happen that a higher temporal resolution is not constantly required because e.g. the measured process variable is constant over a longer period of time. The demand can therefore be different depending on the process conditions.

Furthermore, the measuring device also requires energy to display the measured value on a display or for the operation and / or parameter input via an operating unit. The trend in measuring technology is to design the measuring instruments in such a way that they work as energy-efficiently as possible: four-wire measuring instruments are used in

Increasingly replaced by two-wire gauges. In the case of two-wire measuring devices - in contrast to four-wire measuring devices - energy supply and measured value transmission are done via one and the same

Line pair.

Two-wire gauges must be designed with power requirements in mind so that they can always operate at the power currently available. From EP 1 301 914 B1 a two-wire microwave measuring device with clocked measuring rate has become known. In this known measuring device, the measuring rate is optimized so that a subsequent measurement is always started only when sufficient energy is available for this subsequent measurement.

WO 2004 046 6658 A1 describes an ultrasonic flowmeter with a control / evaluation unit which has a plurality of components, at least one of which has a high power consumption. This component, e.g. an amplifier, an A D converter, a microprocessor, is operated intermittently in a quiescent and in a measuring phase.

From US-PS 6,014,100 a two-wire radar measuring device with constant clocking of the measuring rate has become known, which turns off in the worst or the worst case scenario (worst case) and operates at the lower power limit: The constant clock rate is over the entire measuring range designed so that in the case of the minimum available power, ie with a 4 mA signal, it is ensured that sufficient power is available for the next measurement.

It goes without saying that it is problematic in this known solution, the customer additional features in the operation of the

Meter and evaluation of the measured value. In addition, a constant-rate two-wire meter has a disadvantage over a variable-rate meter has a reduced accuracy over almost the entire measuring range.

In addition to the two-wire measuring devices, which only have a limited energy per unit of time available, energy-self-sufficient measuring devices are increasingly coming into focus in measuring technology. Under the term 'self-sufficient energy

Measuring instruments are subsumed measuring instruments that have no wired lines to any remote energy source. Energy self-sufficient measuring devices are used e.g. powered by at least one battery, by radio, solar cells or fuel cells with energy. In order that the operating time, e.g. the battery is as high as possible, the meters should be designed so that they have the lowest possible power consumption. Due to the limited energy available, it is often difficult to get the

To offer customers two-wire measuring devices with so-called additional features. A classic example of an additional feature of the gauges is a backlit display, a touch screen for easier, an intuitive

Input of the parameter data or for intuitive operation of the device.

The invention has for its object to propose a method that allows an improved, optimized operation of a process measuring device with constant energy consumption. The invention solves the problem by means of a measuring device of

 Process automation technology for measuring at least one process variable of a medium, wherein a control / control unit is provided which measures the process variable to at least a predetermined clock rate and provides as a measured value, with the clock rate, an energy requirement of the

Measuring device is connected, wherein a display / control unit is provided, which represents the measured value and / or the one operation or

Parameter input to the meter allowing the display /

Control unit the control unit of the measuring device of one

Switching the measuring mode into an operating mode, wherein in the operating mode the control unit measures the process variable at a first clock rate, wherein in the measurement mode the control unit measures at a second clock rate, and wherein the first clock rate and the second clock rate are set such that the second clock rate is greater than the first clock rate is and the total energy demand of the meter in the operating mode and in the measuring mode is approximately equal.

An advantageous embodiment of the measuring device according to the invention comprises that the display / operating unit operates in the operating mode with a third clock rate for operation or parameterization of the meter and operates in the measuring operation with a fourth clock rate for displaying the measured values on a display on the meter, wherein the third clock rate is greater than the fourth clock rate. A further embodiment of the measuring device according to the invention provides that in the operating mode, the decrease of the timing of the control / control unit from the second clock rate to the first clock rate is proportional to the increase of the clocking of the display / control unit from the fourth clock rate to the third clock rate that the total energy consumption of the meter remains the same in the operating mode.

A supplementary embodiment of the measuring device according to the invention provides that in the measuring mode, the increase of the clocking of the control / control unit from the first clock rate to the second clock rate is proportional to the decrease of the clocking of the display / control unit from the third clock rate to the fourth clock rate that the total energy demand of the meter remains the same in the metering mode.

 In a particular embodiment of the measuring device according to the invention it is provided that the display / control unit is designed such that when input to the display / control unit, the measuring device of a

Switching the measuring mode to an operating mode.

In a successive embodiment of the measuring device according to the invention it is provided that the measuring device automatically and / or time-controlled according to End of input via the operating elements on the display / operating unit switches from the operating mode back to the measuring mode.

A particularly expedient embodiment of the measuring device according to the invention includes that the measuring device is connected via a two-wire line or a field bus with a remote display / control unit or control center and automatically removed when an input to this

Display / operating unit or remote control center switches from measuring mode to operating mode.

The invention will be explained in more detail with reference to the following drawing. It shows:

1 shows a schematic first embodiment of a measuring device according to the invention with the display / control unit,

In Fig. 1, the construction of a measuring device 1 according to the invention with a display / control unit 2 and a two-wire interface or field bus (6) is shown.

The invention is based on the fundamental idea that the measuring device 1 is operated in at least two different modes: one

Operating mode and a measuring mode. Both modes are different

in terms of the clock rates of the control / control unit 3 and the display / control unit 2. The clock rates of the control / control unit 3 and the display / control unit 2 are chosen so that the respective associated total energy consumption of the measuring device 1 is substantially the same remains. Thus, on the one hand, there is no additional energy for the operation of the

Meter 1 is required and on the other is also the respectively

provided energy in the meter 1 maximum utilized. In the operating mode, the first clock rate of the control / control unit 3 of the measuring device 1 for

Execution and / or evaluation of the measurement of the process variable smaller than the second clock rate of the control / control unit 3 in the measuring mode. Thus be in the measuring mode, more measured values are measured than in the operating mode, which means at the same time that the temporal resolution in the measuring mode is greater. Thus, changes in the process variable can be better monitored over time in the measuring mode. By reducing to the first clock rate of the control / control unit 3 in the measuring device 1 for determining the measured value, energy that is available here is saved, which can be used, for example, for operating the measuring device 1 via the display / operating unit 2. The display / control unit 2 can be operated by the higher, available energy with a higher rate of change of the display on the display 5 or a third clock rate or the query of the input via the

Controls 4 can be done in a higher sampling rate or a third clock rate. Basically, the energy saved in the control unit 3 of the measuring device 1 by reducing it to the first clock rate for measuring the process variable can be restored in the display unit 2, e.g. by increasing to the third clock rate to change the display on the display 5 or to query the controls 4 are used. During configuration or operation on meter 1, the high refresh rate of the readings is no longer as important as outside of the time period in which meter 1 is configured. But you want to allow the customer a quick and easy operation of the meter 1 during this period of operation and / or configuration and in the remaining operating time a fast, accurate measurement of

Allow process size through the meter 1.

List of Reference Instrument

Display / operating unit

Regulation / control unit

controls

display

Fieldbus, two-wire cable

Claims

claims

1 . Measuring device (1) of process automation technology for measuring at least one process variable of a medium,

wherein a control / control unit (3) is provided which measures the process variable at least at a predeterminable clock rate and provides it as a measured value,

wherein an energy requirement of the measuring device (1) is connected to the clock rate, wherein a display / operating unit (2) is provided which represents the measured value and / or which enables an operation or parameter input on the measuring device (1),

characterized,

in that the display / operating unit (2) controls the control unit (3) of the

In the operating mode, the control unit (3) measures the process variable at a first clock rate,

wherein in the measurement mode the control unit (3) measures at a second clock rate, and

wherein the first clock rate and the second clock rate are set such that the second clock rate is greater than the first clock rate and the entire clock rate

Energy requirement of the measuring device (1) in the operating mode and in the

Measuring mode is approximately equal.

2. Apparatus according to claim 1,

characterized,

that the display / operating unit (2) in the operating mode with a third

Clock rate for operation or parameterization of the measuring device (1) operates and operates in Messbetreib with a fourth clock rate for displaying the measured values on a display (5) on the meter (1), wherein the third clock rate is greater than the fourth clock rate.

3. Apparatus according to claim 2,

characterized, in the operating mode, the decrease in the timing of the control unit (3) from the second clock rate to the first clock rate is proportional to the increase in the clocking of the display / control unit (2) from the fourth clock rate to the third clock rate, so that the entire Energy requirement of the measuring device (1) remains the same in the operating mode.

4. Apparatus according to claim 2 or 3,

characterized,

in the measuring mode, the increase in the timing of the control / control unit (3) from the first clock rate to the second clock rate is proportional to the decrease in the clocking of the display / control unit (2) from the third clock rate to the fourth clock rate, so that the entire Energy requirement of the measuring device (1) remains the same in the measuring mode.

5. Apparatus according to claim 2, 3 or 4,

characterized,

in that the display / operating unit (2) is designed in such a way that, when inputting to the display / operating unit (2), the measuring device (1) switches over from a measuring mode to an operating mode.

6. Device according to at least one of the preceding claims, characterized in that

that the measuring device (1) automatically and / or time-controlled after completion of the input via the operating elements (4) on the display / operating unit (2) switches back from the operating mode to the measuring mode.

7. Device according to at least one of the preceding claims,

characterized,

in that the measuring device (1) is connected to a remote display / control unit (2) or control center via a two-wire line (6) or a field bus (6) and automatically when input to this remote display / control unit (2) or remote control center from measurement mode to

Operating mode switches.